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Effect of S-metolachlor and flumioxazin herbicides on sweetpotato treated with and without activated charcoal applied through transplant water

Published online by Cambridge University Press:  01 October 2024

Colton D. Blankenship*
Affiliation:
Graduate Student, Department of Horticultural Science, North Carolina State University, Raleigh, NC, USA
Katherine M. Jennings
Affiliation:
Associate Professor, Department of Horticultural Science, North Carolina State University, Raleigh, NC, USA
David W. Monks
Affiliation:
Professor, Department of Horticultural Science, North Carolina State University, Raleigh, NC, USA
Stephen L. Meyers
Affiliation:
Associate Professor, Department of Horticulture and Landscape Architecture, Purdue University, West Lafayette, IN, USA
David L. Jordan
Affiliation:
Professor, Department of Crop and Soil Sciences, North Carolina State University, Raleigh, NC, USA
Jonathan R. Schultheis
Affiliation:
Professor, Department of Horticultural Science, North Carolina State University, Raleigh, NC, USA
David H. Suchoff
Affiliation:
Assistant Professor, Department of Crop and Soil Sciences, North Carolina State University, Raleigh, NC, USA
Levi D. Moore
Affiliation:
Research Scientist, Southeast Ag Research, Inc., Chula, GA, USA
Stephen J. Ippolito
Affiliation:
Graduate Student, Department of Horticultural Science, North Carolina State University, Raleigh, NC, USA
*
Corresponding author: Colton Blankenship; Email: cdblank3@ncsu.edu
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Abstract

Flumioxazin and S-metolachlor are widely used in conventional sweetpotato production in North Carolina and other states; however, some growers have recently expressed concerns about potential effects of these herbicides on sweetpotato yield and quality. Previous research indicates that activated charcoal has the potential to reduce herbicide injury. Field studies were conducted in 2021 and 2022 to determine whether flumioxazin applied preplant and S-metolachlor applied before and after transplanting negatively affect sweetpotato yield and quality when activated charcoal is applied with transplant water. The studies evaluated five herbicide treatments and two activated charcoal treatments. Herbicide treatments included two flumioxazin rates, one S-metolachlor rate applied immediately before and immediately after transplanting, and no herbicide. Charcoal treatments consisted of activated charcoal applied at 9 kg ha−1, and no charcoal. No visual injury from herbicides or charcoal was observed. Likewise, no effect of herbicide or charcoal treatment on no. 1, marketable (sum of no. 1 and jumbo grades), or total yield (sum of canner, no. 1, and jumbo grades) was observed. Additionally, shape analysis conducted on calculated length-to-width ratio (LWR) for no. 1 sweetpotato roots found no effect from flumioxazin at either rate on sweetpotato root shape. However, both S-metolachlor treatments resulted in lower LWR of no. 1 sweetpotato roots in 2021. Results are consistent with prior research and indicate that flumioxazin and S-metolachlor are safe for continued use on sweetpotato at registered rates.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Weed Science Society of America

Introduction

Sweetpotato is an economically important crop in North Carolina, and in 2021, North Carolina growers harvested 42,000 ha valued at $392 million (USDA-NASS 2022). Nationally over the same period, the United States harvested 62,000 ha of sweetpotato for a total production value of $680 million (USDA-NASS 2022). Sweetpotato is also produced in Arkansas, Florida, Louisiana, Mississippi, and other states throughout the southeastern United States (USDA-NASS 2022).

Weed competition can reduce marketable sweetpotato yield by as much as 86% (Barkley et al. Reference Barkley, Chaudhari, Jennings, Schultheis, Meyers and Monks2016; Basinger et al. Reference Basinger, Jennings, Monks, Jordan, Everman, Hestir, Waldschmidt, Smith and Brownie2019; Meyers et al. Reference Meyers, Jennings, Schultheis and Monks2010b; Smith et al. Reference Smith, Jennings, Monks, Chaudhari, Schultheis and RebergHorton2020). A limited number of herbicides are registered for preemergence control of weeds in sweetpotato crops, including S-metolachlor, flumioxazin, clomazone, DCPA, and fomesafen. Not all these herbicides are registered nationally; for example, S-metolachlor and fomesafen may be used in specific regions of the united States under authority of section 24(c) of the Federal Insecticide, Fungicide, and Rodenticide Act. In addition to herbicides, hand-weeding is a widely used and expensive method of weed control in sweetpotato; North Carolina growers have self-reported hand-weeding costs of up to $370 per hectare (S.C.Smith and L.D. Moore, personal communication).

Flumioxazin, which is used preplant on approximately 90% of conventional sweetpotato hectarage planted in North Carolina (K.M. Jennings, personal communication), delays weed emergence until later in the season and reduces the frequency of expensive hand-weeding. Previous research has indicated that sweetpotato injury and yield reduction from flumioxazin applied before transplantation is minimal (Coleman et al. Reference Coleman, Chaudhari, Jennings, Schultheis, Meyers and Monks2016; Kelly et al. Reference Kelly, Shankle and Miller2006; Meyers et al. Reference Meyers, Jennings, Schultheis and Monks2010a). Although flumioxazin is widely used on sweetpotato, some growers have concerns that flumioxazin may reduce sweetpotato yield or negatively affect root shape. Because flumioxazin is a vital component of many conventional weed management strategies in sweetpotato crop fields, it is important to investigate grower concerns and determine whether flumioxazin is responsible for perceived yield and quality reduction. Likewise, growers have expressed similar concerns about potential injury from S-metolachlor applied to sweetpotato after it has been transplanted. Researchers have reported that S-metolachlor has the potential to injure sweetpotato at high rates and when rain occurs after application (Abukari et al. Reference Abukari, Shankle and Reddy2015; Meyers et al. Reference Meyers, Jennings and Monks2012, Reference Meyers, Jennings and Monks2013). S-metolachlor is a member of the chloroacetamide herbicide family. It is a soil-applied preemergence herbicide that inhibits seedling root and shoot growth by blocking the formation of long-chain fatty acids (Shaner Reference Shaner2014); this activity may explain the reduction in root length observed in previous research.

Charcoal and high-carbon soil additives can reduce herbicide efficacy and crop injury in field conditions (Singh et al. Reference Singh, Masabni, Baumann, Isakeit, Matocha, Provin, Liu, Carson and Bagavathiannan2019; Soni et al. Reference Soni, Leon, Erickson, Ferrell and Silveira2015). Previous research has also shown that dipping crop roots into activated charcoal can reduce herbicide injury in transplanted crops such as strawberry (Fragaria L.) and tobacco (Nicotiana tabacum L.) (Ahrens Reference Ahrens1967; Yelverton et al. Reference Yelverton, Worsham and Peedin1992). However, little information exists on the potential for charcoal to reduce or eliminate herbicide injury to sweetpotato. Thus, we conducted studies to determine the effect of flumioxazin (applied preplant) or S-metolachlor (applied preplant or after transplanting) on sweetpotato injury, storage root yield, and quality with and without activated charcoal applied in transplant water.

Materials and Methods

Field studies were conducted at the Horticultural Crops Research Station in Clinton, NC, in 2021 (35.023°N, 78.280°W) and 2022 (35.022°N, 78.280°W). Soil at the study sites was a Norfolk sandy loam (fine-loamy, kaolinitic, thermic Typic Kandiudults), pH 6.6, with 0.5% organic matter in 2021; and an Orangeburg loamy sand (fine-loamy, kaolinitic, thermic Typic Kandiudults), pH 6.0, with 0.5% organic matter in 2022. On July 8, 2021, and June 9, 2022, nonrooted ‘Covington’ sweetpotato cuttings were transplanted onto weed-free, bedded rows using a commercial mechanical transplanter (Checchi and Magli, Lehi, UT) with an in-row spacing of 30 cm. Plots consisted of two rows, each 1 m wide by 6.1 m long. The first row was a nontreated border row, while the second was used for data collection. All plots were maintained weed-free with between-row cultivation and hand removal of weeds as needed. The statistical design was a randomized complete block with four replications.

Treatments consisted of a factorial arrangement of five herbicide treatments: 1) no herbicide; 2) flumioxazin (Valor SX; Valent U.S.A. LLC, San Ramon, CA) applied pretransplant at 107 g ai ha−1; 3) flumioxazin applied pretransplant at 214 g ai ha−1; 4) S-metolachlor (Dual Magnum; Syngenta, CH) applied pretransplant at 1.6 kg ai ha−1; and 5) S-metolachlor applied immediately after transplanting at 1.6 kg ai ha−1. Also included were two activated charcoal treatments: 1) no activated charcoal was used; or 2) activated charcoal was used in transplant water at 9 kg ha−1, which also included a nonionic surfactant (Induce; Helena Agri Enterprises LLC, Collierville, TN) at 5 ml L−1. Transplant water was applied to each slip through the mechanical transplanter at a rate of 3,648 L ha−1 across all plots. An activated charcoal slurry was made before mixing with transplant water to improve mixing throughout the tank. The activated charcoal suspension was regularly agitated during transplanting to ensure a consistent application. Herbicides were applied with a CO2-pressurized backpack sprayer calibrated to deliver 187 L ha−1 at 173 kPa with a two-nozzle boom equipped with TeeJet XR 8003-VS flat-fan nozzles (Spraying Systems Co., Wheaton, IL). Other production practices, including fertility, and insect and disease management, were conducted following recommendations by Kemble (Reference Kemble2022).

Visual estimates of foliar sweetpotato injury were assessed on a scale of 0% (no crop injury) to 100% (crop death) at 1, 2, 4, and 8 wk after transplanting (Frans et al. Reference Frans, Talbert, Marx, Crowley and Camper1986). Sweetpotato storage roots were harvested 110 d after transplanting with a commercial chain digger, hand-sorted into jumbo (≥8.9 cm in diam), no. 1 (≥4.4 cm but <8.9 cm), and canner (≥2.5 cm but <4.4 cm) (USDA-AMS 2005) grades, and weighed. Marketable yield was calculated as the sum of jumbo and no. 1 yields. Additionally, no. 1 sweetpotato storage root dimensions were assessed using a high-throughput optical grader (Exeter Engineering, Exeter, CA) to quantify treatment effects on storage root shape. Average length-width ratio (LWR) was calculated as the length divided by the diameter for each individual root and then averaged with other roots from the same plot. LWR is a metric that indicates overall sweetpotato root shape and has previously been used as a metric of herbicide injury (Meyers et al. Reference Meyers, Jennings, Schultheis and Monks2010a); a smaller LWR value indicates a rounder sweetpotato root.

Residuals were plotted and visually examined to ensure homogeneity of variance. Yield data required a square root transformation to meet the assumptions of ANOVA. ANOVA was conducted with SAS software (version 9.4; SAS Institute Inc., Cary, NC) using the MIXED procedure. Least squared means were separated using Tukey’s honestly significant difference test (α = 0.05). Herbicide, charcoal, and year were treated as fixed effects, while replication nested within year was treated as a random effect.

Results and Discussion

Crop Injury

No visual injury was observed from flumioxazin applied preplant at rates as high as 214 g ai ha−1 (2× the registered rate) or S-metolachlor as high as 1.6 kg ai ha−1 (2× the recommended rate; Kemble Reference Kemble2022; data not shown). The lack of observed injury is consistent with previous research (Coleman et al. Reference Coleman, Chaudhari, Jennings, Schultheis, Meyers and Monks2016; Kelly et al. Reference Kelly, Shankle and Miller2006; Meyers et al. Reference Meyers, Jennings, Schultheis and Monks2010a).

Sweetpotato Yield

Yield data were combined across years because no significant treatment-by-year interactions were observed (P > 0.05). No effect was observed from herbicide or charcoal treatment on no. 1, marketable, or total yield (P > 0.05). Results indicate that flumioxazin applied at the labeled rate does not reduce sweetpotato yield compared with the nontreated check (Table 1). Additionally, S-metolachlor applied at twice the recommended rate (Kemble Reference Kemble2022) did not reduce sweetpotato yield. Previous research indicates that S-metolachlor can reduce sweetpotato yield under certain environmental conditions (Abukari et al. Reference Abukari, Shankle and Reddy2015; Meyers et al. Reference Meyers, Jennings and Monks2012), but yield reductions due to S-metolachlor application were not observed in this study. The addition of activated charcoal in the transplant water also resulted in no effect on sweetpotato yield. The results of this study confirm the conclusions of prior research and support the safety of applying flumioxazin preplant to sweetpotato when used at registered rates.

Table 1. Effect of flumioxazin and S-metolachlor with and without activated charcoal on sweetpotato storage root yield in Clinton, NC, in 2020 and 2021. a

a No significant treatment effects or interactions were present (P > 0.05). Least squared means with different letters are significantly different.

b Marketable yield is the sum of no. 1 and jumbo grades.

c Total marketable yield is the sum of canner, no. 1, and jumbo grades.

Sweetpotato Storage Root Shape

There was a significant herbicide-by-tear interaction (P = 0.0102) for shape data; thus LWR was assessed by year. Charcoal had no effect on no. 1 LWR, and there were no interactions between charcoal and herbicide (P > 0.05). Herbicide affected LWR in 2021 (P < 0.0001) but not (P = 0.3115) in 2022 (Table 2). In 2021, the LWR was not different between flumioxazin applied at 107 or 214 g ai ha−1, and the no-herbicide treatment. In 2021, S-metolachlor applied at 1.6 kg ai ha−1 before or after transplanting reduced LWR compared to no herbicide treatment, indicating that both S-metolachlor treatments resulted in rounder no. 1 sweetpotato roots. These results are consistent with previous research indicating that S-metolachlor applied directly after transplanting can reduce sweetpotato LWR under certain environmental conditions (Meyers et al. Reference Meyers, Jennings and Monks2012). Limited information exists on the effect of S-metolachlor applications before transplanting on sweetpotato injury and yield; however, because S-metolachlor is registered for use on sweetpotato after transplantation only, the results of this study are consistent with the existing registration and do not suggest that S-metolachlor should be considered for application before transplanting. Flumioxazin did not affect root shape at either the 107 g ai ha−1 (1× registered use) or the 214 g ai ha−1 (2× registered use) rates, which is consistent with previous research (Meyers et al. Reference Meyers, Jennings, Schultheis and Monks2010a).

Table 2. Effect of flumioxazin and S-metolachlor with and without activated charcoal on length to width ratio of no. 1 sweetpotato storage roots in Clinton, NC, in 2020 and 2021. a

a Least squared means were separated by Tukey’s honestly significant difference test at α = 0.05. Means with different letters are significantly different.

Activated charcoal had no effect on sweetpotato yield or quality (grades, shape) across any treatment, indicating either that flumioxazin and S-metolachlor are not injurious enough at the tested rates for the charcoal to make a difference in yield and quality, or that activated charcoal is not an effective safener when mixed with transplant water. Additionally, the effects of S-metolachlor on sweetpotato root shape were not affected by charcoal. More research with additional herbicides is necessary to fully evaluate the potential of activated charcoal mixed with transplant water as a safener for preemergence herbicides on sweetpotato.

Neither flumioxazin nor S-metolachlor reduced sweetpotato yield in this study. The results of this study are consistent with those reported in prior research and indicate that flumioxazin and S-metolachlor are not detrimental to sweetpotato yield when used according to registered rates. Flumioxazin did not affect sweetpotato root shape in either year; however, S-metolachlor use resulted in rounder sweetpotato roots in 2021, indicating that S-metolachlor may affect sweetpotato root shape when applied at higher than registered rates under certain environmental conditions. Although root shape was affected by S-metolachlor in one year, S-metolachlor did not reduce the yield of no. 1 sweetpotato roots. These results are consistent with those found in prior research and indicate that flumioxazin and S-metolachlor are safe for continued use on sweetpotato.

Practical Implications

Because both flumioxazin and S-metolachlor are crucial to existing weed management programs in sweetpotato production in North Carolina, addressing grower concerns about these herbicides is critically important because herbicide options are limited for use on this crop. These studies were conducted in response to grower concerns about potential storage root yield and shape effects from flumioxazin and S-metolachlor, and they provide supporting evidence for their continued use as part of integrated weed management strategies for sweetpotato. This work should improve grower confidence in current recommendations and does not indicate the presence of detrimental yield or shape effects from these herbicides when used according to their respective herbicide label instructions.

Acknowledgements

We thank Stephen Ippolito, Patrick Chang, Chitra, Rebecca Cooper, Rebecca Middleton, Andrew Ippolito, and staff members at the Horticultural Crops Research Station in Clinton, NC, for their help in implementing these studies.

Funding

Funding for this research was supported by the North Carolina SweetPotato Commission. This work was also supported by grant 2019-51300-30247 from the U.S. Department of Agriculture–National Institute for Food and Agriculture. Any opinions, findings, conclusions, or recommendations expressed in this publication are those of the authors and do not necessarily reflect the view of the U.S. Department of Agriculture.

Competing Interests

The authors declare they have no competing interests.

Footnotes

Associate Editor: Robert Nurse, Agriculture and Agri-Food Canada

References

Abukari, IA, Shankle, MW, Reddy, KR (2015) S-metolachlor and rainfall effects on sweetpotato (Ipomoea batatas L. [Lam]) growth and development. Sci Hortic-Amsterdam 185:98104 Google Scholar
Ahrens, J (1967) Improving herbicide selectivity in transplanted crops with root dips of activated charcoal. Pages 64–70 in Proceedings of the 1967 Northeastern Weed Control Conference. King Ferry, NY: Northeastern Weed Science SocietyGoogle Scholar
Barkley, SL, Chaudhari, S, Jennings, KM, Schultheis, JR, Meyers, SL, Monks, DW (2016) Fomesafen programs for Palmer amaranth (Amaranthus palmeri) control in sweetpotato. Weed Technol 30:506515 Google Scholar
Basinger, NT, Jennings, KM, Monks, DW, Jordan, DL, Everman, WJ, Hestir, EL, Waldschmidt, MD, Smith, SC, Brownie, C (2019) Interspecific and intraspecific interference of Palmer amaranth (Amaranthus palmeri) and large crabgrass (Digitaria sanguinalis) in sweetpotato. Weed Sci 67:426432 Google Scholar
Coleman, LB, Chaudhari, S, Jennings, KM, Schultheis, JR, Meyers, SL, Monks, DW (2016) Evaluation of herbicide timings for Palmer amaranth control in a stale seedbed sweetpotato production system. Weed Technol 30:725732 Google Scholar
Frans, RE, Talbert, RE, Marx, D, Crowley, H (1986) Experimental design and techniques for measuring and analyzing plant responses to weed control practices. Pages 2946 in Camper, ND, editor. Research Methods in Weed Science, 3rd ed. Champaign IL: Southern Weed Science Society Google Scholar
Kelly, ST, Shankle, MW, Miller, DK (2006) Efficacy and tolerance of flumioxazin on sweetpotato (Ipomoea batatas). Weed Technol 20:334339 Google Scholar
Kemble, JM, ed. (2022) 2022 Southeastern U.S. Vegetable Crop Handbook. Raleigh, NC: North Carolina State Extension. 376 p. https://content.ces.ncsu.edu/southeastern-us-vegetable-crop-handbook. Accessed: October 4, 2022Google Scholar
Meyers, SL, Jennings, KM, Monks, DW (2012) Response of sweetpotato cultivars to S-metolachlor rate and application time. Weed Technol 26:474479 Google Scholar
Meyers, SL, Jennings, KM, Monks, DW (2013) Herbicide-based weed management programs for Palmer amaranth (Amaranthus palmeri) in sweetpotato. Weed Technol 27:331340 Google Scholar
Meyers, SL, Jennings, KM, Schultheis, JR, Monks, DW (2010a) Evaluation of flumioxazin and S-metolachlor rate and timing for Palmer amaranth (Amaranthus palmeri) control in sweetpotato. Weed Technol 24:495503 Google Scholar
Meyers, SL, Jennings, KM, Schultheis, JR, Monks, DW (2010b) Interference of Palmer amaranth (Amaranthus palmeri) in sweetpotato. Weed Sci 58:199203 Google Scholar
Shaner, DL, editor (2014) Herbicide Handbook, 10th ed. Lawrence, KS: Weed Science Society of America Google Scholar
Singh, V, Masabni, J, Baumann, P, Isakeit, T, Matocha, M, Provin, T, Liu, R, Carson, K, Bagavathiannan, M (2019) Activated charcoal reduces pasture herbicide injury in vegetable crops. Crop Prot 117:16 Google Scholar
Smith, SC, Jennings, KM, Monks, DW, Chaudhari, S, Schultheis, JR, RebergHorton, SC (2020) Critical timing of Palmer amaranth (Amaranthus palmeri) removal in sweetpotato. Weed Technol 34:547551 Google Scholar
Soni, N, Leon, RG, Erickson, JE, Ferrell, JA, Silveira, ML (2015) Biochar decreases atrazine and pendimethalin preemergence herbicidal activity. Weed Technol 29:359366 Google Scholar
[USDA-AMS] U.S Department of Agriculture–Agricultural Marketing Service (2005) United States Standards for Grades of Sweet Potatoes. Washington, DC: U.S. Department of Agriculture Google Scholar
[USDA-NASS] U.S. Department of Agriculture–National Agriculture Statistics Service (2022) Quick stats. https://www.quickstats.nass.usda.gov. Accessed: September 28, 2022Google Scholar
Yelverton, FH, Worsham, AD, Peedin, GF (1992 ) Activated carbon reduces tobacco (Nicotiana tabacum) injury from soil-applied herbicides. Weed Technol 6:310316 Google Scholar
Figure 0

Table 1. Effect of flumioxazin and S-metolachlor with and without activated charcoal on sweetpotato storage root yield in Clinton, NC, in 2020 and 2021.a

Figure 1

Table 2. Effect of flumioxazin and S-metolachlor with and without activated charcoal on length to width ratio of no. 1 sweetpotato storage roots in Clinton, NC, in 2020 and 2021.a